"Universal" max/Tc in Fe Based Superconductors

Abstract

Iron-based superconductors display a large degree of variability in electronic structure at the Fermi surface, resulting in superconducting gap structures,Tc's, and other properties that vary considerably from family to family. Recently it was noted that across many different families of Fe-based systems, the ratio max/Tc is found to be quasi-universal with a large value of ~3.5 compared to the the one-band BCS weak-coupling result of 1.76. Here max is the measured maximum gap across the Fermi surface. This remarkable fact was attributed to strong-coupling effects arising from Hund's metal physics. Here we perform a "high-throughput" scan across band masses, Fermi energies, and interaction parameters in a weak-coupling Suhl-Matthias-Walker model. We find that unexpectedly large values of max/Tc can be achieved within weak coupling, and that quasiuniversal behavior similar to experiment emerges for those systems where interband interactions dominate intraband ones. However, within the current framework, a large mass contrast between bands is required.